BackgroundVideographic material of animals can contain inapparent signals, such as color changes or motion that hold information about physiological functions, such as heart and respiration rate, pulse wave velocity, and vocalization. Eulerian video magnification allows the enhancement of such signals to enable their detection. The purpose of this study is to demonstrate how signals relevant to experimental physiology can be extracted from non-contact videographic material of animals.ResultsWe applied Eulerian video magnification to detect physiological signals in a range of experimental models and in captive and free ranging wildlife. Neotenic Mexican axolotls were studied to demonstrate the extraction of heart rate signal of non-embryonic animals from dedicated videographic material. Heart rate could be acquired both in single and multiple animal setups of leucistic and normally colored animals under different physiological conditions (resting, exercised, or anesthetized) using a wide range of video qualities. Pulse wave velocity could also be measured in the low blood pressure system of the axolotl as well as in the high-pressure system of the human being. Heart rate extraction was also possible from videos of conscious, unconstrained zebrafish and from non-dedicated videographic material of sand lizard and giraffe. This technique also allowed for heart rate detection in embryonic chickens in ovo through the eggshell and in embryonic mice in utero and could be used as a gating signal to acquire two-phase volumetric micro-CT data of the beating embryonic chicken heart. Additionally, Eulerian video magnification was used to demonstrate how vocalization-induced vibrations can be detected in infrasound-producing Asian elephants.ConclusionsEulerian video magnification provides a technique to extract inapparent temporal signals from videographic material of animals. This can be applied in experimental and comparative physiology where contact-based recordings (e.g., heart rate) cannot be acquired.
The cornea is a transparent avascular tissue that transmits light to the retina and covers the lens and iris. According to the World Health Organization, blindness due to injury and disease in the cornea is the fourth leading cause of preventable blindness. Previous research demonstrates that epithelial cells release nucleotides that activate purinergic receptors P2X7 and P2Y2, which induces cell‐cell calcium mobilization. This calcium mobilization is reported to potentially play a role in collective cell migration and wound healing. To better understand this specific mobilization, we studied pannexin, a channel forming glycoprotein. ATP is able to move through the Pannexin channel and binds with P2X7. We want to investigate the mechanism of the calcium signal propagation and whether pannexins are involved. We hypothesize that pannexin channels mediate cell‐cell calcium mobilization and regulates actin activity in response to injury or agonist stimulation. Experiments were performed using 10Panx, an inhibitory peptide for pannexin channels, and scramble Panx, a control peptide. Human Corneal Limbal Epithelial (HCLE) cells were cultured to confluence on glass bottom dishes. Twenty‐four hours prior to experimentation, growth supplements were removed. Cells were preincubated with either 100uM 10Panx or 100uM scramble Panx to inhibit pannexin channels. In order to visualize the change in calcium, cells were pre‐loaded with 5 μM Fluo‐3AM, a fluorescent dye, at a final concentration of 1% (v/v) DMSO and 0.02% (w/v) pluronic acid for 20 minutes at 37°C and 5% CO2. Images were collected every 3 seconds on a Zeiss Axiovert LSM 880 confocal microscope for a period of 45 minutes after either agonist stimulation or injury. The agonist used for stimulation was BzATP, a synthetic nucleotide that selectively activates P2X7 and UTP, an agonist for P2Y2. Baseline and post‐wound frames were captured. Analysis was performed using FIJI/ImageJ and MATLAB programs. We found that 10PanX correlated with dampened calcium mobilization after injury. In uninjured cultures the decrease was only detected in response to BzATP and not to UTP. Actin activity was also inhibited by 10PanX after injury. MATLAB analysis using heatmap indicates that 10PanX reduces correlation of cells during calcium mobilization (Scr BzATP mean: 0.030 10PanXBzATP mean:0.079). Our data indicates that P2X7‐mediated Pannexin channels play a role in the injury response. This provides greater insight as to the level of involvement of pannexin in calcium signal propagation in response to injury in HCLE cells.Support or Funding InformationNIH 5R25HL118693‐05, NIH RO1 EY06000, NIH R21 EY024392, The Mass Lions Foundation New England Corneal Transplant FundThis abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.
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